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Possibilities of predicting the creep of a polymeric fiber-reinforced plastic from the properties of the components

  • Plasticity, Creep, And Rheology Of Solids
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Polymer Mechanics Aims and scope

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Literature cited

  1. G. A. Teters, “Stress redistribution in elements composed of two materials with different creep characteristics”, in: Studies in Plain and Reinforced Concrete, No. 7 [in Russian], Riga (1963), pp. 231–235.

  2. Yu. M. Tarnopol'skii and A. M. Skudra, Structural Strength and Deformation of Glass-Reinforced Plastics [in Russian], Riga (1966).

  3. G. A. Van Fo Fy, Reinforced Plastic Structures [in Russian], Kiev (1971), 219 pp.

  4. A. M. Skudra, F. Ya. Bulavs, and K. A. Rotsens, Creep and Static Fatigue of Reinforced Plastics [in Russian], Riga (1971).

  5. T. V. Borzova, “Stress redistribution in oriented unidirectional glass-reinforced plastics”, in: Scientific Proceedings of the Mechanics Institute of Moscow State University, No. 37 [in Russian], Moscow (1975), pp. 49–54.

  6. T. V. Borzova, “Reduced viscoelastic characteristics of unidirectional glass-reinforced plastics”, in: Deformation and Fracture of Solids [in Russian], Moscow (1977), pp. 105–109.

  7. V. I. Malyi, “Viscoelastic properties of composites”, in: Elasticity and Inelasticity [in Russian], Moscow (1971), pp. 192–201.

  8. T. D. Shermergor, Theory of Elasticity of Microinhomogeneous Media [in Russian], Moscow (1977).

  9. “Superhigh-strength synthetic fiber. Vniivlon N. VNIIV information”, Khim. Volokna, No. 1, 76 (1971).

  10. “A new high-modulus fiber, Ekspress-Informatsiya. Termostoikie Plastiki, No. 4, 12–16 (1973).

  11. K. E. Perepelkin, “Principal structural factors controlling the obtaining of high-strength and high-modulus fibers”, in: Theory of Chemical Fiber Formation [in Russian], Moscow (1975), pp. 221–246.

  12. K. E. Perepelkin, “Limiting mechanical properties of oriented polymer structures used as reinforcement”, in: Fibrous and Filler-Reinforced Composites [in Russian], Moscow (1976), pp. 165–171.

  13. G. P. Mashinskaya, “Organovoloknits — composites reinforced with polymer fibers”, in: Fibrous and Filler-Reinforced Composites [in Russian], Moscow (1976), pp. 171–176.

  14. V. L. Blagonadezhin, N. S. Mezentsev, V. D. Merkulov, and V. D. Polyakov, “Experimental investigation of the physicomechanical characteristics of an organocarbon plastic”, in: Transactions of the Moscow Power Engineering Institute, No. 280 [in Russian] (1976), pp. 43–46.

  15. G. P. Mashinskaya, “Organovoloknits”, in: Structural Plastics [in Russian], Moscow (1974), pp. 226–300.

  16. T. T. Chiao and R. L. Moore, “Organic fibre/epoxide composites”, Composites, No. 1, 31–33 (1973).

  17. M. P. Hanson, “Effect of temperature on the tensile and creep characteristics of PRD-49 fiber/epoxy composites”, Compos. Mater. Eng. Dec. Proc. 6th Symp., St. Louis, 1972, Metals Park, Ohio (1973), pp. 717–724.

  18. R. H. Ericksen, “Room temperature creep of Kevlar 49/epoxy composites”, Composites, No. 7, 189–194 (1976).

  19. A. G. Adamovich, “Time-temperature dependence of the strength of organic fibers based on parapolyamides”, Mekh. Polim., No. 3, 470–473 (1978).

  20. A. G. Adamovich, “Short-time deformation and long-term creep of organic fibers based on parapolyamides”, Abstr. Proc. 1st Conf. Young Specialists in Polymer Mechanics [in Russian], Riga (1977), pp. 36–38.

  21. A. G. Adamovich, “Time-temperature dependence of the strength of a microplastic based on organic fibers”, in: High-Strength Structural Reinforced Polymeric Materials. Materials of a Short Seminar [in Russian], Leingrad (1978), pp. 94–98.

  22. A. F. Kregers, “Algorithm for finding the minimum of a function of many variables by the descent method”, Algoritmy Programmy, No. 2, 9 (1974).

  23. V. V. Moskvitin, Strength of Viscoelastic Materials in Relation to Solid Propellant Rocket Grains [in Russian], Moscow (1972).

  24. M. Ya. Tutan, “Investigation of the acoustic emission of loaded glass-reinforced plasties”, Author's abstract of dissertation for the degree of Candidate of Technical Sciences, Riga (1976).

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Authors
  1. E. A. Sokolov
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  2. R. D. Maksimov
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Additional information

Institute of Polymer Mechanics, Academy of Sciences of the Latvian SSR, Riga. Translated from Mekhanika Polimerov, No. 6, pp. 1005–1012, November–December, 1978.

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Sokolov, E.A., Maksimov, R.D. Possibilities of predicting the creep of a polymeric fiber-reinforced plastic from the properties of the components. Polymer Mechanics 14, 807–813 (1978). https://doi.org/10.1007/BF00860093

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  • DOI: https://doi.org/10.1007/BF00860093

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